Current Path : /sys/amd64/compile/hs32/modules/usr/src/sys/modules/acpi/acpi_panasonic/@/geom/sched/ |
FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //sys/amd64/compile/hs32/modules/usr/src/sys/modules/acpi/acpi_panasonic/@/geom/sched/g_sched.c |
/*- * Copyright (c) 2009-2010 Fabio Checconi * Copyright (c) 2009-2010 Luigi Rizzo, Universita` di Pisa * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHORS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHORS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ /* * $Id$ * $FreeBSD: release/9.1.0/sys/geom/sched/g_sched.c 223921 2011-07-11 05:22:31Z ae $ * * Main control module for geom-based disk schedulers ('sched'). * * USER VIEW * A 'sched' node is typically inserted transparently between * an existing provider pp and its original geom gp * * [pp --> gp ..] * * using the command "geom sched insert <provider>" and * resulting in the following topology * * [pp --> sched_gp --> cp] [new_pp --> gp ... ] * * Deletion "geom sched destroy <provider>.sched." restores the * original chain. The normal "geom sched create <provide>" * is also supported. * * INTERNALS * Internally, the 'sched' uses the following data structures * * geom{} g_sched_softc{} g_gsched{} * +----------+ +---------------+ +-------------+ * | softc *-|--->| sc_gsched *-|-->| gs_init | * | ... | | | | gs_fini | * | | | [ hash table] | | gs_start | * +----------+ | | | ... | * | | +-------------+ * | | * | | g_*_softc{} * | | +-------------+ * | sc_data *-|-->| | * +---------------+ | algorithm- | * | specific | * +-------------+ * * A g_sched_softc{} is created with a "geom sched insert" call. * In turn this instantiates a specific scheduling algorithm, * which sets sc_gsched to point to the algorithm callbacks, * and calls gs_init() to create the g_*_softc{} . * The other callbacks (gs_start, gs_next, ...) are invoked * as needed * * g_sched_softc{} is defined in g_sched.h and mostly used here; * g_gsched{}, and the gs_callbacks, are documented in gs_scheduler.h; * g_*_softc{} is defined/implemented by each algorithm (gs_*.c) * * DATA MOVING * When a bio is received on the provider, it goes to the * g_sched_start() which calls gs_start() to initially queue it; * then we call g_sched_dispatch() that loops around gs_next() * to select zero or more bio's to be sent downstream. * * g_sched_dispatch() can also be called as a result of a timeout, * e.g. when doing anticipation or pacing requests. * * When a bio comes back, it goes to g_sched_done() which in turn * calls gs_done(). The latter does any necessary housekeeping in * the scheduling algorithm, and may decide to call g_sched_dispatch() * to send more bio's downstream. * * If an algorithm needs per-flow queues, these are created * calling gs_init_class() and destroyed with gs_fini_class(), * and they are also inserted in the hash table implemented in * the g_sched_softc{} * * If an algorithm is replaced, or a transparently-inserted node is * removed with "geom sched destroy", we need to remove all references * to the g_*_softc{} and g_sched_softc from the bio's still in * the scheduler. g_sched_forced_dispatch() helps doing this. * XXX need to explain better. */ #include <sys/cdefs.h> #include <sys/param.h> #include <sys/systm.h> #include <sys/kernel.h> #include <sys/module.h> #include <sys/lock.h> #include <sys/mutex.h> #include <sys/bio.h> #include <sys/limits.h> #include <sys/hash.h> #include <sys/sbuf.h> #include <sys/sysctl.h> #include <sys/malloc.h> #include <sys/proc.h> /* we access curthread */ #include <geom/geom.h> #include "gs_scheduler.h" #include "g_sched.h" /* geom hooks */ /* * Size of the per-geom hash table storing traffic classes. * We may decide to change it at a later time, it has no ABI * implications as it is only used for run-time allocations. */ #define G_SCHED_HASH_SIZE 32 static int g_sched_destroy(struct g_geom *gp, boolean_t force); static int g_sched_destroy_geom(struct gctl_req *req, struct g_class *mp, struct g_geom *gp); static void g_sched_config(struct gctl_req *req, struct g_class *mp, const char *verb); static struct g_geom *g_sched_taste(struct g_class *mp, struct g_provider *pp, int flags __unused); static void g_sched_dumpconf(struct sbuf *sb, const char *indent, struct g_geom *gp, struct g_consumer *cp, struct g_provider *pp); static void g_sched_init(struct g_class *mp); static void g_sched_fini(struct g_class *mp); static int g_sched_ioctl(struct g_provider *pp, u_long cmd, void *data, int fflag, struct thread *td); struct g_class g_sched_class = { .name = G_SCHED_CLASS_NAME, .version = G_VERSION, .ctlreq = g_sched_config, .taste = g_sched_taste, .destroy_geom = g_sched_destroy_geom, .init = g_sched_init, .ioctl = g_sched_ioctl, .fini = g_sched_fini }; MALLOC_DEFINE(M_GEOM_SCHED, "GEOM_SCHED", "Geom schedulers data structures"); /* * Global variables describing the state of the geom_sched module. * There is only one static instance of this structure. */ LIST_HEAD(gs_list, g_gsched); /* type, link field */ struct geom_sched_vars { struct mtx gs_mtx; struct gs_list gs_scheds; /* list of algorithms */ u_int gs_debug; u_int gs_sched_count; /* how many algorithms ? */ u_int gs_patched; /* g_io_request was patched */ u_int gs_initialized; u_int gs_expire_secs; /* expiration of hash entries */ struct bio_queue_head gs_pending; u_int gs_npending; /* The following are for stats, usually protected by gs_mtx. */ u_long gs_requests; /* total requests */ u_long gs_done; /* total done */ u_int gs_in_flight; /* requests in flight */ u_int gs_writes_in_flight; u_int gs_bytes_in_flight; u_int gs_write_bytes_in_flight; char gs_names[256]; /* names of schedulers */ }; static struct geom_sched_vars me = { .gs_expire_secs = 10, }; SYSCTL_DECL(_kern_geom); SYSCTL_NODE(_kern_geom, OID_AUTO, sched, CTLFLAG_RW, 0, "GEOM_SCHED stuff"); SYSCTL_UINT(_kern_geom_sched, OID_AUTO, in_flight_wb, CTLFLAG_RD, &me.gs_write_bytes_in_flight, 0, "Write bytes in flight"); SYSCTL_UINT(_kern_geom_sched, OID_AUTO, in_flight_b, CTLFLAG_RD, &me.gs_bytes_in_flight, 0, "Bytes in flight"); SYSCTL_UINT(_kern_geom_sched, OID_AUTO, in_flight_w, CTLFLAG_RD, &me.gs_writes_in_flight, 0, "Write Requests in flight"); SYSCTL_UINT(_kern_geom_sched, OID_AUTO, in_flight, CTLFLAG_RD, &me.gs_in_flight, 0, "Requests in flight"); SYSCTL_ULONG(_kern_geom_sched, OID_AUTO, done, CTLFLAG_RD, &me.gs_done, 0, "Total done"); SYSCTL_ULONG(_kern_geom_sched, OID_AUTO, requests, CTLFLAG_RD, &me.gs_requests, 0, "Total requests"); SYSCTL_STRING(_kern_geom_sched, OID_AUTO, algorithms, CTLFLAG_RD, &me.gs_names, 0, "Algorithm names"); SYSCTL_UINT(_kern_geom_sched, OID_AUTO, alg_count, CTLFLAG_RD, &me.gs_sched_count, 0, "Number of algorithms"); SYSCTL_UINT(_kern_geom_sched, OID_AUTO, debug, CTLFLAG_RW, &me.gs_debug, 0, "Debug level"); SYSCTL_UINT(_kern_geom_sched, OID_AUTO, expire_secs, CTLFLAG_RW, &me.gs_expire_secs, 0, "Expire time in seconds"); /* * g_sched calls the scheduler algorithms with this lock held. * The locking functions are exposed so the scheduler algorithms can also * protect themselves e.g. when running a callout handler. */ void g_sched_lock(struct g_geom *gp) { struct g_sched_softc *sc = gp->softc; mtx_lock(&sc->sc_mtx); } void g_sched_unlock(struct g_geom *gp) { struct g_sched_softc *sc = gp->softc; mtx_unlock(&sc->sc_mtx); } /* * Support functions to handle references to the module, * which are coming from devices using this scheduler. */ static inline void g_gsched_ref(struct g_gsched *gsp) { atomic_add_int(&gsp->gs_refs, 1); } static inline void g_gsched_unref(struct g_gsched *gsp) { atomic_add_int(&gsp->gs_refs, -1); } /* * Update the stats when this request is done. */ static void g_sched_update_stats(struct bio *bio) { me.gs_done++; me.gs_in_flight--; me.gs_bytes_in_flight -= bio->bio_length; if (bio->bio_cmd & BIO_WRITE) { me.gs_writes_in_flight--; me.gs_write_bytes_in_flight -= bio->bio_length; } } /* * Dispatch any pending request. */ static void g_sched_forced_dispatch(struct g_geom *gp) { struct g_sched_softc *sc = gp->softc; struct g_gsched *gsp = sc->sc_gsched; struct bio *bp; KASSERT(mtx_owned(&sc->sc_mtx), ("sc_mtx not owned during forced dispatch")); while ((bp = gsp->gs_next(sc->sc_data, 1)) != NULL) g_io_request(bp, LIST_FIRST(&gp->consumer)); } /* * The main dispatch loop, called either here after the start * routine, or by scheduling algorithms when they receive a timeout * or a 'done' notification. Does not share code with the forced * dispatch path, since the gs_done() callback can call us. */ void g_sched_dispatch(struct g_geom *gp) { struct g_sched_softc *sc = gp->softc; struct g_gsched *gsp = sc->sc_gsched; struct bio *bp; KASSERT(mtx_owned(&sc->sc_mtx), ("sc_mtx not owned during dispatch")); if ((sc->sc_flags & G_SCHED_FLUSHING)) return; while ((bp = gsp->gs_next(sc->sc_data, 0)) != NULL) g_io_request(bp, LIST_FIRST(&gp->consumer)); } /* * Recent (8.0 and above) versions of FreeBSD have support to * register classifiers of disk requests. The classifier is * invoked by g_io_request(), and stores the information into * bp->bio_classifier1. * * Support for older versions, which is left here only for * documentation purposes, relies on two hacks: * 1. classification info is written into the bio_caller1 * field of the topmost node in the bio chain. This field * is rarely used, but this module is incompatible with * those that use bio_caller1 for other purposes, * such as ZFS and gjournal; * 2. g_io_request() is patched in-memory when the module is * loaded, so that the function calls a classifier as its * first thing. g_io_request() is restored when the module * is unloaded. This functionality is only supported for * x86 and amd64, other architectures need source code changes. */ /* * Lookup the identity of the issuer of the original request. * In the current implementation we use the curthread of the * issuer, but different mechanisms may be implemented later * so we do not make assumptions on the return value which for * us is just an opaque identifier. */ static inline u_long g_sched_classify(struct bio *bp) { #if __FreeBSD_version > 800098 /* we have classifier fields in the struct bio */ #define HAVE_BIO_CLASSIFIER return ((u_long)bp->bio_classifier1); #else #warning old version!!! while (bp->bio_parent != NULL) bp = bp->bio_parent; return ((u_long)bp->bio_caller1); #endif } /* Return the hash chain for the given key. */ static inline struct g_hash * g_sched_hash(struct g_sched_softc *sc, u_long key) { return (&sc->sc_hash[key & sc->sc_mask]); } /* * Helper function for the children classes, which takes * a geom and a bio and returns the private descriptor * associated to the request. This involves fetching * the classification field and [al]locating the * corresponding entry in the hash table. */ void * g_sched_get_class(struct g_geom *gp, struct bio *bp) { struct g_sched_softc *sc; struct g_sched_class *gsc; struct g_gsched *gsp; struct g_hash *bucket; u_long key; sc = gp->softc; key = g_sched_classify(bp); bucket = g_sched_hash(sc, key); LIST_FOREACH(gsc, bucket, gsc_clist) { if (key == gsc->gsc_key) { gsc->gsc_refs++; return (gsc->gsc_priv); } } gsp = sc->sc_gsched; gsc = malloc(sizeof(*gsc) + gsp->gs_priv_size, M_GEOM_SCHED, M_NOWAIT | M_ZERO); if (!gsc) return (NULL); if (gsp->gs_init_class(sc->sc_data, gsc->gsc_priv)) { free(gsc, M_GEOM_SCHED); return (NULL); } gsc->gsc_refs = 2; /* 1 for the hash table, 1 for the caller. */ gsc->gsc_key = key; LIST_INSERT_HEAD(bucket, gsc, gsc_clist); gsc->gsc_expire = ticks + me.gs_expire_secs * hz; return (gsc->gsc_priv); } /* * Release a reference to the per-client descriptor, */ void g_sched_put_class(struct g_geom *gp, void *priv) { struct g_sched_class *gsc; struct g_sched_softc *sc; gsc = g_sched_priv2class(priv); gsc->gsc_expire = ticks + me.gs_expire_secs * hz; if (--gsc->gsc_refs > 0) return; sc = gp->softc; sc->sc_gsched->gs_fini_class(sc->sc_data, priv); LIST_REMOVE(gsc, gsc_clist); free(gsc, M_GEOM_SCHED); } static void g_sched_hash_fini(struct g_geom *gp, struct g_hash *hp, u_long mask, struct g_gsched *gsp, void *data) { struct g_sched_class *cp, *cp2; int i; if (!hp) return; if (data && gsp->gs_hash_unref) gsp->gs_hash_unref(data); for (i = 0; i < G_SCHED_HASH_SIZE; i++) { LIST_FOREACH_SAFE(cp, &hp[i], gsc_clist, cp2) g_sched_put_class(gp, cp->gsc_priv); } hashdestroy(hp, M_GEOM_SCHED, mask); } static struct g_hash * g_sched_hash_init(struct g_gsched *gsp, u_long *mask, int flags) { struct g_hash *hash; if (gsp->gs_priv_size == 0) return (NULL); hash = hashinit_flags(G_SCHED_HASH_SIZE, M_GEOM_SCHED, mask, flags); return (hash); } static void g_sched_flush_classes(struct g_geom *gp) { struct g_sched_softc *sc; struct g_sched_class *cp, *cp2; int i; sc = gp->softc; if (!sc->sc_hash || ticks - sc->sc_flush_ticks <= 0) return; for (i = 0; i < G_SCHED_HASH_SIZE; i++) { LIST_FOREACH_SAFE(cp, &sc->sc_hash[i], gsc_clist, cp2) { if (cp->gsc_refs == 1 && ticks - cp->gsc_expire > 0) g_sched_put_class(gp, cp->gsc_priv); } } sc->sc_flush_ticks = ticks + me.gs_expire_secs * hz; } /* * Wait for the completion of any outstanding request. To ensure * that this does not take forever the caller has to make sure that * no new request enter the scehduler before calling us. * * Must be called with the gp mutex held and topology locked. */ static int g_sched_wait_pending(struct g_geom *gp) { struct g_sched_softc *sc = gp->softc; int endticks = ticks + hz; g_topology_assert(); while (sc->sc_pending && endticks - ticks >= 0) msleep(gp, &sc->sc_mtx, 0, "sched_wait_pending", hz / 4); return (sc->sc_pending ? ETIMEDOUT : 0); } static int g_sched_remove_locked(struct g_geom *gp, struct g_gsched *gsp) { struct g_sched_softc *sc = gp->softc; int error; /* Set the flushing flag: new bios will not enter the scheduler. */ sc->sc_flags |= G_SCHED_FLUSHING; g_sched_forced_dispatch(gp); error = g_sched_wait_pending(gp); if (error) goto failed; /* No more requests pending or in flight from the old gsp. */ g_sched_hash_fini(gp, sc->sc_hash, sc->sc_mask, gsp, sc->sc_data); sc->sc_hash = NULL; /* * Avoid deadlock here by releasing the gp mutex and reacquiring * it once done. It should be safe, since no reconfiguration or * destruction can take place due to the geom topology lock; no * new request can use the current sc_data since we flagged the * geom as being flushed. */ g_sched_unlock(gp); gsp->gs_fini(sc->sc_data); g_sched_lock(gp); sc->sc_gsched = NULL; sc->sc_data = NULL; g_gsched_unref(gsp); failed: sc->sc_flags &= ~G_SCHED_FLUSHING; return (error); } static int g_sched_remove(struct g_geom *gp, struct g_gsched *gsp) { int error; g_sched_lock(gp); error = g_sched_remove_locked(gp, gsp); /* gsp is surely non-null */ g_sched_unlock(gp); return (error); } /* * Support function for create/taste -- locate the desired * algorithm and grab a reference to it. */ static struct g_gsched * g_gsched_find(const char *name) { struct g_gsched *gsp = NULL; mtx_lock(&me.gs_mtx); LIST_FOREACH(gsp, &me.gs_scheds, glist) { if (strcmp(name, gsp->gs_name) == 0) { g_gsched_ref(gsp); break; } } mtx_unlock(&me.gs_mtx); return (gsp); } /* * Rebuild the list of scheduler names. * To be called with me.gs_mtx lock held. */ static void g_gsched_build_names(struct g_gsched *gsp) { int pos, l; struct g_gsched *cur; pos = 0; LIST_FOREACH(cur, &me.gs_scheds, glist) { l = strlen(cur->gs_name); if (l + pos + 1 + 1 < sizeof(me.gs_names)) { if (pos != 0) me.gs_names[pos++] = ' '; strcpy(me.gs_names + pos, cur->gs_name); pos += l; } } me.gs_names[pos] = '\0'; } /* * Register or unregister individual scheduling algorithms. */ static int g_gsched_register(struct g_gsched *gsp) { struct g_gsched *cur; int error = 0; mtx_lock(&me.gs_mtx); LIST_FOREACH(cur, &me.gs_scheds, glist) { if (strcmp(gsp->gs_name, cur->gs_name) == 0) break; } if (cur != NULL) { G_SCHED_DEBUG(0, "A scheduler named %s already" "exists.", gsp->gs_name); error = EEXIST; } else { LIST_INSERT_HEAD(&me.gs_scheds, gsp, glist); gsp->gs_refs = 1; me.gs_sched_count++; g_gsched_build_names(gsp); } mtx_unlock(&me.gs_mtx); return (error); } struct g_gsched_unregparm { struct g_gsched *gup_gsp; int gup_error; }; static void g_gsched_unregister(void *arg, int flag) { struct g_gsched_unregparm *parm = arg; struct g_gsched *gsp = parm->gup_gsp, *cur, *tmp; struct g_sched_softc *sc; struct g_geom *gp, *gp_tmp; int error; parm->gup_error = 0; g_topology_assert(); if (flag == EV_CANCEL) return; mtx_lock(&me.gs_mtx); LIST_FOREACH_SAFE(gp, &g_sched_class.geom, geom, gp_tmp) { if (gp->class != &g_sched_class) continue; /* Should not happen. */ sc = gp->softc; if (sc->sc_gsched == gsp) { error = g_sched_remove(gp, gsp); if (error) goto failed; } } LIST_FOREACH_SAFE(cur, &me.gs_scheds, glist, tmp) { if (cur != gsp) continue; if (gsp->gs_refs != 1) { G_SCHED_DEBUG(0, "%s still in use.", gsp->gs_name); parm->gup_error = EBUSY; } else { LIST_REMOVE(gsp, glist); me.gs_sched_count--; g_gsched_build_names(gsp); } break; } if (cur == NULL) { G_SCHED_DEBUG(0, "%s not registered.", gsp->gs_name); parm->gup_error = ENOENT; } failed: mtx_unlock(&me.gs_mtx); } static inline void g_gsched_global_init(void) { if (!me.gs_initialized) { G_SCHED_DEBUG(0, "Initializing global data."); mtx_init(&me.gs_mtx, "gsched", NULL, MTX_DEF); LIST_INIT(&me.gs_scheds); gs_bioq_init(&me.gs_pending); me.gs_initialized = 1; } } /* * Module event called when a scheduling algorithm module is loaded or * unloaded. */ int g_gsched_modevent(module_t mod, int cmd, void *arg) { struct g_gsched *gsp = arg; struct g_gsched_unregparm parm; int error; G_SCHED_DEBUG(0, "Modevent %d.", cmd); /* * If the module is loaded at boot, the geom thread that calls * g_sched_init() might actually run after g_gsched_modevent(), * so make sure that the module is properly initialized. */ g_gsched_global_init(); error = EOPNOTSUPP; switch (cmd) { case MOD_LOAD: error = g_gsched_register(gsp); G_SCHED_DEBUG(0, "Loaded module %s error %d.", gsp->gs_name, error); if (error == 0) g_retaste(&g_sched_class); break; case MOD_UNLOAD: parm.gup_gsp = gsp; parm.gup_error = 0; error = g_waitfor_event(g_gsched_unregister, &parm, M_WAITOK, NULL); if (error == 0) error = parm.gup_error; G_SCHED_DEBUG(0, "Unloaded module %s error %d.", gsp->gs_name, error); break; }; return (error); } #ifdef KTR #define TRC_BIO_EVENT(e, bp) g_sched_trace_bio_ ## e (bp) static inline char g_sched_type(struct bio *bp) { if (0 != (bp->bio_cmd & BIO_READ)) return ('R'); else if (0 != (bp->bio_cmd & BIO_WRITE)) return ('W'); return ('U'); } static inline void g_sched_trace_bio_START(struct bio *bp) { CTR5(KTR_GSCHED, "S %lu %c %lu/%lu %lu", g_sched_classify(bp), g_sched_type(bp), bp->bio_offset / ULONG_MAX, bp->bio_offset, bp->bio_length); } static inline void g_sched_trace_bio_DONE(struct bio *bp) { CTR5(KTR_GSCHED, "D %lu %c %lu/%lu %lu", g_sched_classify(bp), g_sched_type(bp), bp->bio_offset / ULONG_MAX, bp->bio_offset, bp->bio_length); } #else /* !KTR */ #define TRC_BIO_EVENT(e, bp) #endif /* !KTR */ /* * g_sched_done() and g_sched_start() dispatch the geom requests to * the scheduling algorithm in use. */ static void g_sched_done(struct bio *bio) { struct g_geom *gp = bio->bio_caller2; struct g_sched_softc *sc = gp->softc; TRC_BIO_EVENT(DONE, bio); KASSERT(bio->bio_caller1, ("null bio_caller1 in g_sched_done")); g_sched_lock(gp); g_sched_update_stats(bio); sc->sc_gsched->gs_done(sc->sc_data, bio); if (!--sc->sc_pending) wakeup(gp); g_sched_flush_classes(gp); g_sched_unlock(gp); g_std_done(bio); } static void g_sched_start(struct bio *bp) { struct g_geom *gp = bp->bio_to->geom; struct g_sched_softc *sc = gp->softc; struct bio *cbp; TRC_BIO_EVENT(START, bp); G_SCHED_LOGREQ(bp, "Request received."); cbp = g_clone_bio(bp); if (cbp == NULL) { g_io_deliver(bp, ENOMEM); return; } cbp->bio_done = g_sched_done; cbp->bio_to = LIST_FIRST(&gp->provider); KASSERT(cbp->bio_to != NULL, ("NULL provider")); /* We only schedule reads and writes. */ if (0 == (bp->bio_cmd & (BIO_READ | BIO_WRITE))) goto bypass; G_SCHED_LOGREQ(cbp, "Sending request."); g_sched_lock(gp); /* * Call the algorithm's gs_start to queue the request in the * scheduler. If gs_start fails then pass the request down, * otherwise call g_sched_dispatch() which tries to push * one or more requests down. */ if (!sc->sc_gsched || (sc->sc_flags & G_SCHED_FLUSHING) || sc->sc_gsched->gs_start(sc->sc_data, cbp)) { g_sched_unlock(gp); goto bypass; } /* * We use bio_caller1 to mark requests that are scheduled * so make sure it is not NULL. */ if (cbp->bio_caller1 == NULL) cbp->bio_caller1 = &me; /* anything not NULL */ cbp->bio_caller2 = gp; sc->sc_pending++; /* Update general stats. */ me.gs_in_flight++; me.gs_requests++; me.gs_bytes_in_flight += bp->bio_length; if (bp->bio_cmd & BIO_WRITE) { me.gs_writes_in_flight++; me.gs_write_bytes_in_flight += bp->bio_length; } g_sched_dispatch(gp); g_sched_unlock(gp); return; bypass: cbp->bio_done = g_std_done; cbp->bio_caller1 = NULL; /* not scheduled */ g_io_request(cbp, LIST_FIRST(&gp->consumer)); } /* * The next few functions are the geom glue. */ static void g_sched_orphan(struct g_consumer *cp) { g_topology_assert(); g_sched_destroy(cp->geom, 1); } static int g_sched_access(struct g_provider *pp, int dr, int dw, int de) { struct g_geom *gp; struct g_consumer *cp; int error; gp = pp->geom; cp = LIST_FIRST(&gp->consumer); error = g_access(cp, dr, dw, de); return (error); } static void g_sched_temporary_start(struct bio *bio) { mtx_lock(&me.gs_mtx); me.gs_npending++; gs_bioq_disksort(&me.gs_pending, bio); mtx_unlock(&me.gs_mtx); } static void g_sched_flush_pending(g_start_t *start) { struct bio *bp; while ((bp = gs_bioq_takefirst(&me.gs_pending))) start(bp); } static int g_insert_proxy(struct g_geom *gp, struct g_provider *newpp, struct g_geom *dstgp, struct g_provider *pp, struct g_consumer *cp) { struct g_sched_softc *sc = gp->softc; g_start_t *saved_start, *flush = g_sched_start; int error = 0, endticks = ticks + hz; g_cancel_event(newpp); /* prevent taste() */ /* copy private fields */ newpp->private = pp->private; newpp->index = pp->index; /* Queue all the early requests coming for us. */ me.gs_npending = 0; saved_start = pp->geom->start; dstgp->start = g_sched_temporary_start; while (pp->nstart - pp->nend != me.gs_npending && endticks - ticks >= 0) tsleep(pp, PRIBIO, "-", hz/10); if (pp->nstart - pp->nend != me.gs_npending) { flush = saved_start; error = ETIMEDOUT; goto fail; } /* link pp to this geom */ LIST_REMOVE(pp, provider); pp->geom = gp; LIST_INSERT_HEAD(&gp->provider, pp, provider); /* * replicate the counts from the parent in the * new provider and consumer nodes */ cp->acr = newpp->acr = pp->acr; cp->acw = newpp->acw = pp->acw; cp->ace = newpp->ace = pp->ace; sc->sc_flags |= G_SCHED_PROXYING; fail: dstgp->start = saved_start; g_sched_flush_pending(flush); return (error); } /* * Create a geom node for the device passed as *pp. * If successful, add a reference to this gsp. */ static int g_sched_create(struct gctl_req *req, struct g_class *mp, struct g_provider *pp, struct g_gsched *gsp, int proxy) { struct g_sched_softc *sc = NULL; struct g_geom *gp, *dstgp; struct g_provider *newpp = NULL; struct g_consumer *cp = NULL; char name[64]; int error; g_topology_assert(); snprintf(name, sizeof(name), "%s%s", pp->name, G_SCHED_SUFFIX); LIST_FOREACH(gp, &mp->geom, geom) { if (strcmp(gp->name, name) == 0) { gctl_error(req, "Geom %s already exists.", name); return (EEXIST); } } gp = g_new_geomf(mp, name); dstgp = proxy ? pp->geom : gp; /* where do we link the provider */ sc = g_malloc(sizeof(*sc), M_WAITOK | M_ZERO); sc->sc_gsched = gsp; sc->sc_data = gsp->gs_init(gp); if (sc->sc_data == NULL) { error = ENOMEM; goto fail; } sc->sc_hash = g_sched_hash_init(gsp, &sc->sc_mask, HASH_WAITOK); /* * Do not initialize the flush mechanism, will be initialized * on the first insertion on the hash table. */ mtx_init(&sc->sc_mtx, "g_sched_mtx", NULL, MTX_DEF); gp->softc = sc; gp->start = g_sched_start; gp->orphan = g_sched_orphan; gp->access = g_sched_access; gp->dumpconf = g_sched_dumpconf; newpp = g_new_providerf(dstgp, gp->name); newpp->mediasize = pp->mediasize; newpp->sectorsize = pp->sectorsize; cp = g_new_consumer(gp); error = g_attach(cp, proxy ? newpp : pp); if (error != 0) { gctl_error(req, "Cannot attach to provider %s.", pp->name); goto fail; } g_error_provider(newpp, 0); if (proxy) { error = g_insert_proxy(gp, newpp, dstgp, pp, cp); if (error) goto fail; } G_SCHED_DEBUG(0, "Device %s created.", gp->name); g_gsched_ref(gsp); return (0); fail: if (cp != NULL) { if (cp->provider != NULL) g_detach(cp); g_destroy_consumer(cp); } if (newpp != NULL) g_destroy_provider(newpp); if (sc->sc_hash) g_sched_hash_fini(gp, sc->sc_hash, sc->sc_mask, gsp, sc->sc_data); if (sc->sc_data) gsp->gs_fini(sc->sc_data); g_free(gp->softc); g_destroy_geom(gp); return (error); } /* * Support for dynamic switching of scheduling algorithms. * First initialize the data structures for the new algorithm, * then call g_sched_remove_locked() to flush all references * to the old one, finally link the new algorithm. */ static int g_sched_change_algo(struct gctl_req *req, struct g_class *mp, struct g_provider *pp, struct g_gsched *gsp) { struct g_sched_softc *sc; struct g_geom *gp; struct g_hash *newh; void *data; u_long mask; int error = 0; gp = pp->geom; sc = gp->softc; data = gsp->gs_init(gp); if (data == NULL) return (ENOMEM); newh = g_sched_hash_init(gsp, &mask, HASH_WAITOK); if (gsp->gs_priv_size && !newh) { error = ENOMEM; goto fail; } g_sched_lock(gp); if (sc->sc_gsched) { /* can be NULL in some cases */ error = g_sched_remove_locked(gp, sc->sc_gsched); if (error) goto fail; } g_gsched_ref(gsp); sc->sc_gsched = gsp; sc->sc_data = data; sc->sc_hash = newh; sc->sc_mask = mask; g_sched_unlock(gp); return (0); fail: if (newh) g_sched_hash_fini(gp, newh, mask, gsp, data); if (data) gsp->gs_fini(data); g_sched_unlock(gp); return (error); } /* * Stop the request flow directed to the proxy, redirecting the new * requests to the me.gs_pending queue. */ static struct g_provider * g_detach_proxy(struct g_geom *gp) { struct g_consumer *cp; struct g_provider *pp, *newpp; do { pp = LIST_FIRST(&gp->provider); if (pp == NULL) break; cp = LIST_FIRST(&gp->consumer); if (cp == NULL) break; newpp = cp->provider; if (newpp == NULL) break; me.gs_npending = 0; pp->geom->start = g_sched_temporary_start; return (pp); } while (0); printf("%s error detaching proxy %s\n", __FUNCTION__, gp->name); return (NULL); } static void g_sched_blackhole(struct bio *bp) { g_io_deliver(bp, ENXIO); } static inline void g_reparent_provider(struct g_provider *pp, struct g_geom *gp, struct g_provider *newpp) { LIST_REMOVE(pp, provider); if (newpp) { pp->private = newpp->private; pp->index = newpp->index; } pp->geom = gp; LIST_INSERT_HEAD(&gp->provider, pp, provider); } static inline void g_unproxy_provider(struct g_provider *oldpp, struct g_provider *newpp) { struct g_geom *gp = oldpp->geom; g_reparent_provider(oldpp, newpp->geom, newpp); /* * Hackish: let the system destroy the old provider for us, just * in case someone attached a consumer to it, in which case a * direct call to g_destroy_provider() would not work. */ g_reparent_provider(newpp, gp, NULL); } /* * Complete the proxy destruction, linking the old provider to its * original geom, and destroying the proxy provider. Also take care * of issuing the pending requests collected in me.gs_pending (if any). */ static int g_destroy_proxy(struct g_geom *gp, struct g_provider *oldpp) { struct g_consumer *cp; struct g_provider *newpp; do { cp = LIST_FIRST(&gp->consumer); if (cp == NULL) break; newpp = cp->provider; if (newpp == NULL) break; /* Relink the provider to its original geom. */ g_unproxy_provider(oldpp, newpp); /* Detach consumer from provider, and destroy provider. */ cp->acr = newpp->acr = 0; cp->acw = newpp->acw = 0; cp->ace = newpp->ace = 0; g_detach(cp); /* Send the pending bios through the right start function. */ g_sched_flush_pending(oldpp->geom->start); return (0); } while (0); printf("%s error destroying proxy %s\n", __FUNCTION__, gp->name); /* We cannot send the pending bios anywhere... */ g_sched_flush_pending(g_sched_blackhole); return (EINVAL); } static int g_sched_destroy(struct g_geom *gp, boolean_t force) { struct g_provider *pp, *oldpp = NULL; struct g_sched_softc *sc; struct g_gsched *gsp; int error; g_topology_assert(); sc = gp->softc; if (sc == NULL) return (ENXIO); if (!(sc->sc_flags & G_SCHED_PROXYING)) { pp = LIST_FIRST(&gp->provider); if (pp && (pp->acr != 0 || pp->acw != 0 || pp->ace != 0)) { const char *msg = force ? "but we force removal" : "cannot remove"; G_SCHED_DEBUG(!force, "Device %s is still open (r%dw%de%d), %s.", pp->name, pp->acr, pp->acw, pp->ace, msg); if (!force) return (EBUSY); } else { G_SCHED_DEBUG(0, "Device %s removed.", gp->name); } } else oldpp = g_detach_proxy(gp); gsp = sc->sc_gsched; if (gsp) { /* * XXX bad hack here: force a dispatch to release * any reference to the hash table still held by * the scheduler. */ g_sched_lock(gp); /* * We are dying here, no new requests should enter * the scheduler. This is granted by the topolgy, * either in case we were proxying (new bios are * being redirected) or not (see the access check * above). */ g_sched_forced_dispatch(gp); error = g_sched_wait_pending(gp); if (error) { /* * Not all the requests came home: this might happen * under heavy load, or if we were waiting for any * bio which is served in the event path (see * geom_slice.c for an example of how this can * happen). Try to restore a working configuration * if we can fail. */ if ((sc->sc_flags & G_SCHED_PROXYING) && oldpp) { g_sched_flush_pending(force ? g_sched_blackhole : g_sched_start); } /* * In the forced destroy case there is not so much * we can do, we have pending bios that will call * g_sched_done() somehow, and we don't want them * to crash the system using freed memory. We tell * the user that something went wrong, and leak some * memory here. * Note: the callers using force = 1 ignore the * return value. */ if (force) { G_SCHED_DEBUG(0, "Pending requests while " " destroying geom, some memory leaked."); } return (error); } g_sched_unlock(gp); g_sched_hash_fini(gp, sc->sc_hash, sc->sc_mask, gsp, sc->sc_data); sc->sc_hash = NULL; gsp->gs_fini(sc->sc_data); g_gsched_unref(gsp); sc->sc_gsched = NULL; } if ((sc->sc_flags & G_SCHED_PROXYING) && oldpp) { error = g_destroy_proxy(gp, oldpp); if (error) { if (force) { G_SCHED_DEBUG(0, "Unrecoverable error while " "destroying a proxy geom, leaking some " " memory."); } return (error); } } mtx_destroy(&sc->sc_mtx); g_free(gp->softc); gp->softc = NULL; g_wither_geom(gp, ENXIO); return (error); } static int g_sched_destroy_geom(struct gctl_req *req, struct g_class *mp, struct g_geom *gp) { return (g_sched_destroy(gp, 0)); } /* * Functions related to the classification of requests. * * On recent FreeBSD versions (8.0 and above), we store a reference * to the issuer of a request in bp->bio_classifier1 as soon * as the bio is posted to the geom queue (and not later, because * requests are managed by the g_down thread afterwards). * * On older versions of the system (but this code is not used * in any existing release), we [ab]use the caller1 field in the * root element of the bio tree to store the classification info. * The marking is done at the beginning of g_io_request() * and only if we find that the field is NULL. * * To avoid rebuilding the kernel, this module will patch the * initial part of g_io_request() so it jumps to some hand-coded * assembly that does the marking and then executes the original * body of g_io_request(). * * fake_ioreq[] is architecture-specific machine code * that implements the above. CODE_SIZE, STORE_SIZE etc. * are constants used in the patching routine. Look at the * code in g_ioreq_patch() for the details. */ #ifndef HAVE_BIO_CLASSIFIER /* * Support for old FreeBSD versions */ #if defined(__i386__) #define CODE_SIZE 29 #define STORE_SIZE 5 #define EPILOGUE 5 #define SIZE (CODE_SIZE + STORE_SIZE + EPILOGUE) static u_char fake_ioreq[SIZE] = { 0x8b, 0x44, 0x24, 0x04, /* mov bp, %eax */ /* 1: */ 0x89, 0xc2, /* mov %eax, %edx # edx = bp */ 0x8b, 0x40, 0x64, /* mov bp->bio_parent, %eax */ 0x85, 0xc0, /* test %eax, %eax */ 0x75, 0xf7, /* jne 1b */ 0x8b, 0x42, 0x30, /* mov bp->bp_caller1, %eax */ 0x85, 0xc0, /* test %eax, %eax */ 0x75, 0x09, /* jne 2f */ 0x64, 0xa1, 0x00, 0x00, /* mov %fs:0, %eax */ 0x00, 0x00, 0x89, 0x42, 0x30, /* mov %eax, bp->bio_caller1 */ /* 2: */ 0x55, 0x89, 0xe5, 0x57, 0x56, 0xe9, 0x00, 0x00, 0x00, 0x00, /* jmp back... */ }; #elif defined(__amd64) #define CODE_SIZE 38 #define STORE_SIZE 6 #define EPILOGUE 5 #define SIZE (CODE_SIZE + STORE_SIZE + EPILOGUE) static u_char fake_ioreq[SIZE] = { 0x48, 0x89, 0xf8, /* mov bp, %rax */ /* 1: */ 0x48, 0x89, 0xc2, /* mov %rax, %rdx # rdx = bp */ 0x48, 0x8b, 0x82, 0xa8, /* mov bp->bio_parent, %rax */ 0x00, 0x00, 0x00, 0x48, 0x85, 0xc0, /* test %rax, %rax */ 0x75, 0xf1, /* jne 1b */ 0x48, 0x83, 0x7a, 0x58, /* cmp $0, bp->bp_caller1 */ 0x00, 0x75, 0x0d, /* jne 2f */ 0x65, 0x48, 0x8b, 0x04, /* mov %gs:0, %rax */ 0x25, 0x00, 0x00, 0x00, 0x00, 0x48, 0x89, 0x42, 0x58, /* mov %rax, bp->bio_caller1 */ /* 2: */ 0x55, 0x48, 0x89, 0xe5, 0x41, 0x56, 0xe9, 0x00, 0x00, 0x00, 0x00, /* jmp back... */ }; #else /* neither x86 nor amd64 */ static void g_new_io_request(struct bio *bp, struct g_consumer *cp) { struct bio *top = bp; /* * bio classification: if bio_caller1 is available in the * root of the 'struct bio' tree, store there the thread id * of the thread that originated the request. * More sophisticated classification schemes can be used. */ while (top->bio_parent) top = top->bio_parent; if (top->bio_caller1 == NULL) top->bio_caller1 = curthread; } #error please add the code above in g_new_io_request() to the beginning of \ /sys/geom/geom_io.c::g_io_request(), and remove this line. #endif /* end of arch-specific code */ static int g_ioreq_patch(void) { u_char *original; u_long ofs; int found; if (me.gs_patched) return (-1); original = (u_char *)g_io_request; found = !bcmp(original, fake_ioreq + CODE_SIZE, STORE_SIZE); if (!found) return (-1); /* Jump back to the original + STORE_SIZE. */ ofs = (original + STORE_SIZE) - (fake_ioreq + SIZE); bcopy(&ofs, fake_ioreq + CODE_SIZE + STORE_SIZE + 1, 4); /* Patch the original address with a jump to the trampoline. */ *original = 0xe9; /* jump opcode */ ofs = fake_ioreq - (original + 5); bcopy(&ofs, original + 1, 4); me.gs_patched = 1; return (0); } /* * Restore the original code, this is easy. */ static void g_ioreq_restore(void) { u_char *original; if (me.gs_patched) { original = (u_char *)g_io_request; bcopy(fake_ioreq + CODE_SIZE, original, STORE_SIZE); me.gs_patched = 0; } } static inline void g_classifier_ini(void) { g_ioreq_patch(); } static inline void g_classifier_fini(void) { g_ioreq_restore(); } /*--- end of support code for older FreeBSD versions */ #else /* HAVE_BIO_CLASSIFIER */ /* * Classifier support for recent FreeBSD versions: we use * a very simple classifier, only use curthread to tag a request. * The classifier is registered at module load, and unregistered * at module unload. */ static int g_sched_tag(void *arg, struct bio *bp) { bp->bio_classifier1 = curthread; return (1); } static struct g_classifier_hook g_sched_classifier = { .func = g_sched_tag, }; static inline void g_classifier_ini(void) { g_register_classifier(&g_sched_classifier); } static inline void g_classifier_fini(void) { g_unregister_classifier(&g_sched_classifier); } #endif /* HAVE_BIO_CLASSIFIER */ static void g_sched_init(struct g_class *mp) { g_gsched_global_init(); G_SCHED_DEBUG(0, "Loading: mp = %p, g_sched_class = %p.", mp, &g_sched_class); /* Patch g_io_request to store classification info in the bio. */ g_classifier_ini(); } static void g_sched_fini(struct g_class *mp) { g_classifier_fini(); G_SCHED_DEBUG(0, "Unloading..."); KASSERT(LIST_EMPTY(&me.gs_scheds), ("still registered schedulers")); mtx_destroy(&me.gs_mtx); } static int g_sched_ioctl(struct g_provider *pp, u_long cmd, void *data, int fflag, struct thread *td) { struct g_consumer *cp; struct g_geom *gp; cp = LIST_FIRST(&pp->geom->consumer); if (cp == NULL) return (ENOIOCTL); gp = cp->provider->geom; if (gp->ioctl == NULL) return (ENOIOCTL); return (gp->ioctl(cp->provider, cmd, data, fflag, td)); } /* * Read the i-th argument for a request, skipping the /dev/ * prefix if present. */ static const char * g_sched_argi(struct gctl_req *req, int i) { static const char *dev_prefix = "/dev/"; const char *name; char param[16]; int l = strlen(dev_prefix); snprintf(param, sizeof(param), "arg%d", i); name = gctl_get_asciiparam(req, param); if (name == NULL) gctl_error(req, "No 'arg%d' argument", i); else if (strncmp(name, dev_prefix, l) == 0) name += l; return (name); } /* * Fetch nargs and do appropriate checks. */ static int g_sched_get_nargs(struct gctl_req *req) { int *nargs; nargs = gctl_get_paraml(req, "nargs", sizeof(*nargs)); if (nargs == NULL) { gctl_error(req, "No 'nargs' argument"); return (0); } if (*nargs <= 0) gctl_error(req, "Missing device(s)."); return (*nargs); } /* * Check whether we should add the class on certain volumes when * this geom is created. Right now this is under control of a kenv * variable containing the names of all devices that we care about. * Probably we should only support transparent insertion as the * preferred mode of operation. */ static struct g_geom * g_sched_taste(struct g_class *mp, struct g_provider *pp, int flags __unused) { struct g_gsched *gsp = NULL; /* the . algorithm we want */ const char *s; /* generic string pointer */ const char *taste_names; /* devices we like */ int l; g_trace(G_T_TOPOLOGY, "%s(%s, %s)", __func__, mp->name, pp->name); g_topology_assert(); G_SCHED_DEBUG(2, "Tasting %s.", pp->name); do { /* do not taste on ourselves */ if (pp->geom->class == mp) break; taste_names = getenv("geom.sched.taste"); if (taste_names == NULL) break; l = strlen(pp->name); for (s = taste_names; *s && (s = strstr(s, pp->name)); s++) { /* further checks for an exact match */ if ( (s == taste_names || s[-1] == ' ') && (s[l] == '\0' || s[l] == ' ') ) break; } if (s == NULL) break; G_SCHED_DEBUG(0, "Attach device %s match [%s]\n", pp->name, s); /* look up the provider name in the list */ s = getenv("geom.sched.algo"); if (s == NULL) s = "rr"; gsp = g_gsched_find(s); /* also get a reference */ if (gsp == NULL) { G_SCHED_DEBUG(0, "Bad '%s' algorithm.", s); break; } /* XXX create with 1 as last argument ? */ g_sched_create(NULL, mp, pp, gsp, 0); g_gsched_unref(gsp); } while (0); return NULL; } static void g_sched_ctl_create(struct gctl_req *req, struct g_class *mp, int proxy) { struct g_provider *pp; struct g_gsched *gsp; const char *name; int i, nargs; g_topology_assert(); name = gctl_get_asciiparam(req, "algo"); if (name == NULL) { gctl_error(req, "No '%s' argument", "algo"); return; } gsp = g_gsched_find(name); /* also get a reference */ if (gsp == NULL) { gctl_error(req, "Bad algorithm '%s'", name); return; } nargs = g_sched_get_nargs(req); /* * Run on the arguments, and break on any error. * We look for a device name, but skip the /dev/ prefix if any. */ for (i = 0; i < nargs; i++) { name = g_sched_argi(req, i); if (name == NULL) break; pp = g_provider_by_name(name); if (pp == NULL) { G_SCHED_DEBUG(1, "Provider %s is invalid.", name); gctl_error(req, "Provider %s is invalid.", name); break; } if (g_sched_create(req, mp, pp, gsp, proxy) != 0) break; } g_gsched_unref(gsp); } static void g_sched_ctl_configure(struct gctl_req *req, struct g_class *mp) { struct g_provider *pp; struct g_gsched *gsp; const char *name; int i, nargs; g_topology_assert(); name = gctl_get_asciiparam(req, "algo"); if (name == NULL) { gctl_error(req, "No '%s' argument", "algo"); return; } gsp = g_gsched_find(name); /* also get a reference */ if (gsp == NULL) { gctl_error(req, "Bad algorithm '%s'", name); return; } nargs = g_sched_get_nargs(req); /* * Run on the arguments, and break on any error. * We look for a device name, but skip the /dev/ prefix if any. */ for (i = 0; i < nargs; i++) { name = g_sched_argi(req, i); if (name == NULL) break; pp = g_provider_by_name(name); if (pp == NULL || pp->geom->class != mp) { G_SCHED_DEBUG(1, "Provider %s is invalid.", name); gctl_error(req, "Provider %s is invalid.", name); break; } if (g_sched_change_algo(req, mp, pp, gsp) != 0) break; } g_gsched_unref(gsp); } static struct g_geom * g_sched_find_geom(struct g_class *mp, const char *name) { struct g_geom *gp; LIST_FOREACH(gp, &mp->geom, geom) { if (strcmp(gp->name, name) == 0) return (gp); } return (NULL); } static void g_sched_ctl_destroy(struct gctl_req *req, struct g_class *mp) { int nargs, *force, error, i; struct g_geom *gp; const char *name; g_topology_assert(); nargs = g_sched_get_nargs(req); force = gctl_get_paraml(req, "force", sizeof(*force)); if (force == NULL) { gctl_error(req, "No 'force' argument"); return; } for (i = 0; i < nargs; i++) { name = g_sched_argi(req, i); if (name == NULL) break; gp = g_sched_find_geom(mp, name); if (gp == NULL) { G_SCHED_DEBUG(1, "Device %s is invalid.", name); gctl_error(req, "Device %s is invalid.", name); break; } error = g_sched_destroy(gp, *force); if (error != 0) { gctl_error(req, "Cannot destroy device %s (error=%d).", gp->name, error); break; } } } static void g_sched_config(struct gctl_req *req, struct g_class *mp, const char *verb) { uint32_t *version; g_topology_assert(); version = gctl_get_paraml(req, "version", sizeof(*version)); if (version == NULL) { gctl_error(req, "No '%s' argument.", "version"); return; } if (*version != G_SCHED_VERSION) { gctl_error(req, "Userland and kernel parts are " "out of sync."); return; } if (strcmp(verb, "create") == 0) { g_sched_ctl_create(req, mp, 0); return; } else if (strcmp(verb, "insert") == 0) { g_sched_ctl_create(req, mp, 1); return; } else if (strcmp(verb, "configure") == 0) { g_sched_ctl_configure(req, mp); return; } else if (strcmp(verb, "destroy") == 0) { g_sched_ctl_destroy(req, mp); return; } gctl_error(req, "Unknown verb."); } static void g_sched_dumpconf(struct sbuf *sb, const char *indent, struct g_geom *gp, struct g_consumer *cp, struct g_provider *pp) { struct g_sched_softc *sc = gp->softc; struct g_gsched *gsp = sc->sc_gsched; if (indent == NULL) { /* plaintext */ sbuf_printf(sb, " algo %s", gsp ? gsp->gs_name : "--"); } if (gsp != NULL && gsp->gs_dumpconf) gsp->gs_dumpconf(sb, indent, gp, cp, pp); } DECLARE_GEOM_CLASS(g_sched_class, g_sched); MODULE_VERSION(geom_sched, 0);